Karolin Luger

Crystal structure of the nucleosome core particle at 2.8 A resolution

The X-ray crystal structure of the nucleosome core particle of chromatin shows in atomic detail how the histone protein octamer is assembled and how 146 base pairs of DNA are organized into a superhelix around it. Both histone/histone and histone/DNA interactions depend on the histone fold domains and additional, well ordered structure elements extending from this motif. Histone amino-terminal tails pass over and between the gyres of the DNA superhelix to contact neighbouring particles. The lack of uniformity between multiple histone/DNA-binding sites causes the DNA to deviate from ideal superhelix geometry.

Solvent Mediated Interactions in the Structure of the Nucleosome Core Particle at 1.9 A Resolution

Solvent binding in the nucleosome core particle containing a 147 base pair, defined-sequence DNA is characterized from the X-ray crystal structure at 1.9 A resolution. A single-base-pair increase in DNA length over that used previously results in substantially improved clarity of the electron density and accuracy for the histone protein and DNA atomic coordinates. The reduced disorder has allowed for the first time extensive modeling of water molecules and ions. Over 3000 water molecules and 18 ions have been identified. Water molecules acting as hydrogen-bond bridges between protein and DNA are approximately equal in number to the direct hydrogen bonds between these components. Bridging water molecules have a dual role in promoting histone-DNA association not only by providing further stability to direct protein-DNA interactions, but also by enabling formation of many additional interactions between more distantly related elements. Water molecules residing in the minor groove play an important role in facilitating insertion of arginine side-chains. Water structure at the interface of the histones and DNA provides a means of accommodating intrinsic DNA conformational variation, thus limiting the sequence dependency of nucleosome positioning while enhancing mobility. Monovalent anions are bound near the N termini of histone alpha-helices that are not occluded by DNA phosphate groups. Their location in proximity to the DNA phosphodiester backbone suggests that they damp the electrostatic interaction between the histone proteins and the DNA. Divalent cations are bound at specific sites in the nucleosome core particle and contribute to histone-histone and histone-DNA interparticle interactions. These interactions may be relevant to nucleosome association in arrays.

Preparation of nucleosome core particle from recombinant histones

Publisher Summary This chapter describes the preparation method of nucleosome core particles (NCPs) from recombinant histones. The ability to make defined NCPs, or arrays of nucleosomes, from histone proteins expressed in bacteria has several advantages over previously used methods using histones isolated from natural sources. The chapter discusses protocols for the overexpression and purification of histones H2A, H2B, H3, and H4, both as full-length proteins and as corresponding trypsin-resistant globular domains. The chapter presents a method for the refolding and purification of a histone octamer from denatured recombinant histone proteins together with a protocol for the assembly and purification of a nucleosome core particle using 146 base pairs of DNA. The purity and homogeneity of the final core-particle preparation are assessed by a high-resolution gel shift assay. The chapter presents a flow chart that describes the procedures involved in the preparation of synthetic nucleosomes.

Crystal structure of a nucleosome core particle containing the variant histone H2A.Z.

Activation of transcription within chromatin has been correlated with the incorporation of the essential histone variant H2A.Z into nucleosomes. H2A.Z and other histone variants may establish structurally distinct chromosomal domains; however, the molecular mechanism by which they function is largely unknown. Here we report the 2.6 Å crystal structure of a nucleosome core particle containing the histone variant H2A.Z. The overall structure is similar to that of the previously reported 2.8 Å nucleosome structure containing major histone proteins. However, distinct localized changes result in the subtle destabilization of the interaction between the (H2A.Z–H2B) dimer and the (H3–H4)2 tetramer. Moreover, H2A.Z nucleosomes have an altered surface that includes a metal ion. This altered surface may lead to changes in higher order structure, and/or could result in the association of specific nuclear proteins with H2A.Z. Finally, incorporation of H2A.Z and H2A within the same nucleosome is unlikely, due to significant changes in the interface between the two H2A.Z–H2B dimers.

The histone tails of the nucleosome.

Reversible acetylation of core histone tails plays an important role in the regulation of eukaryotic transcription, in the formation of repressive chromatin complexes, and in the inactivation of whole chromosomes. The high-resolution X-ray structure of the nucleosome core particle, as well as earlier evidence, suggests that the histone tails are largely responsible for the assembly of nucleosomes into chromatin fibers and implies that the physiological effects of histone acetylation may be achieved by modulation of a dynamic inter-conversion between the fiber and a less condensed nucleofilament structure. In addition, the tails and adjacent regions serve as recognition sites for chromatin assembly and transcription remodeling machinery and the interactions that occur may also be responsive to histone acetylation.

Reconstitution of Nucleosome Core Particles from Recombinant Histones and DNA

Publisher Summary The ability to prepare nucleosome core particles (NCPs), or nucleosomal arrays, from recombinant histone proteins and defined-sequence DNA has become a requirement in many projects that address the role of histone modifications, histone variants, or histone mutations in nucleosome and chromatin structure. The cloning strategies for the construction of plasmids containing multiple repeats of defined DNA sequences, and the subsequent large-scale isolation of defined sequence DNA for nucleosome reconstitution are described. This chapter also describes adapted procedures to prepare nucleosomes with histones from other species, and for the refolding and reconstitution of (H2A– H2B) dimers and (H3–H4) 2 tetramers. Methods to reconstitute nucleosomes from different histone subcomplexes are described. A flow chart for all procedures involved in the preparation of synthetic nucleosomes is also presented.

Structural determinants for generating centromeric chromatin

Mammalian centromeres are not defined by a consensus DNA sequence. In all eukaryotes a hallmark of functional centromeres—both normal ones and those formed aberrantly at atypical loci—is the accumulation of centromere protein A (CENP-A), a histone variant that replaces H3 in centromeric nucleosomes. Here we show using deuterium exchange/mass spectrometry coupled with hydrodynamic measures that CENP-A and histone H4 form sub-nucleosomal tetramers that are more compact and conformationally more rigid than the corresponding tetramers of histones H3 and H4. Substitution into histone H3 of the domain of CENP-A responsible for compaction is sufficient to direct it to centromeres. Thus, the centromere-targeting domain of CENP-A confers a unique structural rigidity to the nucleosomes into which it assembles, and is likely to have a role in maintaining centromere identity.

New insights into nucleosome and chromatin structure: an ordered state or a disordered affair?

The compaction of genomic DNA into chromatin has profound implications for the regulation of key processes such as transcription, replication and DNA repair. Nucleosomes, the repeating building blocks of chromatin, vary in the composition of their histone protein components. This is the result of the incorporation of variant histones and post-translational modifications of histone amino acid side chains. The resulting changes in nucleosome structure, stability and dynamics affect the compaction of nucleosomal arrays into higher-order structures. It is becoming clear that chromatin structures are not nearly as uniform and regular as previously assumed. This implies that chromatin structure must also be viewed in the context of specific biological functions.

Structure of the yeast nucleosome core particle reveals fundamental changes in internucleosome interactions.

Chromatin is composed of nucleosomes, the universally repeating protein—DNA complex in eukaryotic cells. The crystal structure of the nucleosome core particle from Saccharomyces cerevisiae reveals that the structure and function of this fundamental complex is conserved between single‐cell organisms and metazoans. Our results show that yeast nucleosomes are likely to be subtly destabilized as compared with nucleosomes from higher eukaryotes, consistent with the idea that much of the yeast genome remains constitutively open during much of its life cycle. Importantly, minor sequence variations lead to dramatic changes in the way in which nucleosomes pack against each other within the crystal lattice. This has important implications for our understanding of the formation of higher order chromatin structure and its modulation by post‐translational modifications. Finally, the yeast nucleosome core particle provides a structural context by which to interpret genetic data obtained from yeast. Coordinates have been deposited with the Protein Data Bank under accession number 1ID3.

DNA binding within the nucleosome core.

The high resolution structure of the nucleosome core particle of chromatin reveals the form of DNA that is predominant in living cells and offers a wealth of information on DNA binding and bending by the histone octamer. Recent studies imply that chromatin is highly dynamic. This propensity for unfolding and refolding stems from the structural design of the nucleosome core. The histone-fold motif, central to nucleosome structure, is also found in other proteins involved in transcriptional regulation.